FR2867620A1 - FREQUENCY OFFSET DEVICE IN A CONTINUOUS LASER SOURCE OPTICAL PATH - Google Patents

Abstract

The present invention relates to a frequency shift device in an optical path with a continuous emission laser source, and it is characterized in that it comprises at least one frequency shift module containing an optical propagation medium which is modified. the length of the optical path as a function of the desired frequency offset.Application: lidars.

Description

FREQUENCY OFFSET DEVICE IN A PATH

OPTICAL LASER SOURCE CONTINUES

  The present invention relates to a frequency shifting device in a continuous emission laser source optical path.

  In devices having a continuous emission laser source and heterodyne coherent detection, it may be necessary to determine a frequency variation (Doppler effect) occurring on a portion of the laser beam path and resulting from a physical phenomenon that the we want to compensate or measure. This is particularly the case of Lidars used to measure the speed and direction of the wind by backscattering the laser beam on aerosols carried by the wind. This frequency variation is generally determined by mixing the received signal with a signal generated by a local oscillator and affected by a frequency offset produced by an electro-optical or acousto-optical type modulator.

  Such a modulator device is expensive, bulky, not very discrete, because it radiates at high frequency (presence of harmonic lines of the fundamental frequency of the signal, likely to disturb the signal processing performed downstream, which may limit the accuracy of the signal. velocity measurement and shrink the spectral measurement window.

  The subject of the present invention is a frequency shifting device in a continuous emission laser source optical path, which device is as inexpensive as possible, not cumbersome, which is not a source of parasitic radiation, and which can be integrated in an architecture comprising optical fibers.

  The device according to the invention comprises at least one frequency shift module containing an optical propagation medium whose optical path length is modified as a function of the desired frequency offset. The optical propagation medium may be either an optical fiber, an optical waveguide or an electrooptical crystal.

  In the case where the system in which the frequency is varied is a Lidar, the evolution of the optical path length of the optical propagation support is advantageously linear, and it is performed by linear evolution of the stress applied to the optical fiber. or the waveguide or the voltage applied to the electro-optical crystal.

  Advantageously, at least two frequency shifting modules are connected in parallel. their respective triangular modulations being identical and shifted in phase, a switch being connected to the outputs of these modules and controlled to alternately collect the optical beam whose frequency offset is constant.

  The present invention will be better understood on reading the detailed description of an embodiment, taken by way of nonlimiting example and illustrated by the appended drawing, in which: FIG. 1 is a simplified block diagram of a Lidar of FIG. 2 is a simplified block diagram of a Lidar comprising a frequency shift circuit according to the invention, and FIG. example of a set of two frequency shift modules according to the invention.

  The present invention is described below with reference to a Lidar, but it is understood that it is not limited to this single application, and that it can be implemented in various fields in which it is necessary. to produce a frequency shift on high frequencies such as frequencies above a few Ghz.

  There is shown in the block diagram of Figure 1 a laser source 1 connected to an input of a polarization maintaining coupler 2. A first output of the coupler 2, corresponding to the signal path, is connected to an acousto-optic modulator 3, followed by an amplifier 4. The amplifier 4 is connected to a first terminal of a coupler 5 with polarization separation. An output of the coupler 5 is connected to a Lidar beam transceiver system, referenced 6 as a whole. The second output of the coupler 2 is connected to a first input of a polarization-maintaining coupler 7, the other input of which is connected to the coupler 5. The output of the coupler 7 is connected to a mixing and detection unit 8, followed by a filter circuit 9 and signal processing circuits 10.

  In the block diagram of FIG. 2, the elements similar to those of FIG. 1 are assigned the same reference numerals. The essential difference between the systems of FIGS. 1 and 2 is that the modulator 3 of FIG. 1 has been replaced by a device 11 with frequency shift modules. The other elements of the system of Figure 2 may be the same as those of Figure 1.

  The device 11 may comprise one or more elementary frequency shift modules. Each of these elementary modules comprises an optical propagation medium such as an optical fiber, an optical waveguide or an electro-optical crystal. It acts on this support so as to vary the length of the optical path. This variation in path length corresponds to a variation of the refractive index of the optical medium. In the case where this support is an optical fiber or a waveguide, this variation can be obtained by imposing a mechanical stress on the optical medium. If it is an electro-optical crystal, the variation is obtained by applying an appropriate voltage to its electrodes. In this regard, it is important to note that the electro-optical crystal does not operate in conventional electro-optic modulator, but in a device causing a shift, fixed or variable, the frequency of the laser beam it receives.

  The evolution of the mechanical stress or the electrical voltage must, in this case, be linear as a function of time. This linear evolution generates a constant Doppler shift, and therefore a fixed frequency offset between the signal and local oscillator paths, which allows consistent heterodyne detection. This Doppler shift is imposed on the signal path in which the device 11 is inserted (as shown in solid lines in FIG. 2), and / or in the local oscillator channel (the second shift module device is then referenced 11A and drawn in broken lines in Figure 2). A variation in the length of the optical path is generated when the speed of the beam passing through the device 11 (and / or 11A) varies. This speed varies inversely with the refractive index of the medium through which it passes. According to the invention, the length of the optical path in the device 11 (and / or 11A) is linearly varied as a function of time, which generates a constant Doppler shift. According to an advantageous aspect of the invention, and as shown in FIG. 3, the device 11 (and / or 11A) is provided with two identical offset modules 12, 13, connected in parallel, and followed by a switch 14. It is understood that the device 11 (and / or 11A) may have more than two modules. In each of the modules 12, 13, an identical triangular modulation is applied, the modulation in one of the two modules being shifted in phase, for example ir, relative to that of the other. However, such a value is not imperative, and it suffices that the two channels are shifted by half a period so that, at the output of the switch, the frequency offset is always constant. . The upward and downward slopes of these triangular modulations may be identical, but may also be different, for example the downward slope may be much stronger than the other. In the present case, only the ascending slopes are used, by alternately switching the switch 14 to the output of the module 12 and the module 13. The phase shift between the two triangular modulations must preferably be such that the peak of the ascending part of one corresponds at least to the beginning of the ascending part of the other. Thus, there is obtained at the output of the switch 14 a fixed Doppler shift without interruptions.

  However, according to one variant of the invention, either a single shift module is used, the switch 14 is then deleted, or at least two modules, but in these two cases only one part (upwards, example) of modulation among n consecutive, the same direction of variation (n may be greater than 2 or even 10). Such a characteristic requires the interruption of the emission of the laser beam during the generation of the unused modulation parts (upward and / or downward parts), but makes it possible to raise a doubt while awaiting the arrival of the real echo , corresponding to a laser beam portion emitted during an up-modulation part, before emitting the next beam portion.

  According to a variant of the invention, the laser beam is passed through the shifter two or more times. The first reason is of an economic nature: if the slope in applied voltage is not sufficient to obtain the desired offset over the duration of the pulse, the beam is again passed through the beam to reach the desired final offset. The second reason is that the offset module could very well be located behind the coupler 5, just before the emission of the beam into the atmosphere, in which case the backscattered beam could itself undergo a shift (identical or opposite or other than the initial offset).

  The frequency offset generated by the device 11 (and / or 11A) can be controlled using the value of the offset measurement at the output of each offset module. The electrooptic control voltage or the mechanical stress applied to the optical propagation medium of these modules (and thus the slope and the shape of the corresponding modulation, and consequently the law of evolution of the frequency offset) can then be slaved to a value fixed or evolving according to a specific law which is a function of the considered application, as for example in the case where phenomena of narcissus (parasitic reflections) occur. This frequency offset measurement may be used in the postprocessing performed in the signal processing circuitry of the backscattered signal. The invention is also applicable when performing BLU mixtures (in phase and in quadrature phase).

  The applications of the device of the invention are numerous: besides the application considered here to the telemetry and velocimetry Lidars, with, if necessary, chirped beams, mention will be made of telecommunications (multiplexers and demultiplexers, for example, etc.). of the invention, by replacing the conventional acoustooptic or electro-optic modulator by a shift device with optical path length variation, makes it possible to avoid the emission of disturbing harmonic lines, and to avoid the production of a The mechanical or electrical stresses involved in this shifting device are small and therefore easy to produce.The electro-optical technologies used by the invention are derived from those commonly used in telecommunications, the components used being compact and relatively small. expensive, because made in integrated technique.It can further reduce the costs of c components by hybridizing them to a planar waveguide, reducing the number of wire and fiber optic connections.

Claims (10)

  A frequency shifting device (11, 11A) in a continuous emission laser source optical path, characterized in that it comprises at least one frequency shift module (12, 13) containing an optical propagation medium of which the length of the optical path is changed according to the desired frequency offset.   2. Device according to claim 1, characterized in that the optical propagation medium is one of the following devices: an optical fiber, a waveguide or an electro-optical crystal.   3. Device according to claim 1 or 2, characterized in that the system in which the frequency is varied is a Lidar and that the evolution of the optical path length of the optical propagation medium is linear.   4. Device according to claim 3, characterized in that the linear evolution is sequentially increasing, then decreasing according to a triangular modulation law.   5. Device according to claim 4, characterized in that the slopes of the ascending and descending segments of the triangular modulation law are equal.   6. Device according to claim 4, characterized in that the slopes of the ascending and descending segments of the triangular modulation law are different.   7. Device according to one of the preceding claims, characterized in that is connected in parallel at least two frequency shift modules and their respective triangular modulations are identical and shifted in phase, a switch (14) being connected to the outputs of these modules and controlled to collect alternately the optical beam whose frequency offset is constant.   8. Device according to one of the preceding claims, characterized in that it uses only one modulation part among consecutive n of the same direction of variation to achieve a lifting of doubt at the arrival of the echoes.   9. Device according to one of the preceding claims, characterized in that the law of evolution of the frequency offset is slaved to a fixed value.   10. Device according to one of claims 1 to 8, characterized in that the law of evolution of the frequency offset is controlled by a variable value.